Download 02b_geometricoptics_14inch_lpc

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

CoRoT wikipedia , lookup

Hipparcos wikipedia , lookup

James Webb Space Telescope wikipedia , lookup

XMM-Newton wikipedia , lookup

Spitzer Space Telescope wikipedia , lookup

CfA 1.2 m Millimeter-Wave Telescope wikipedia , lookup

International Ultraviolet Explorer wikipedia , lookup

Very Large Telescope wikipedia , lookup

Reflecting telescope wikipedia , lookup

Optical telescope wikipedia , lookup

Transcript
Physics Part 3
OPTICS
Telescopes
(Optical Instruments)
W. Pezzaglia
Updated: 2012Apr18
Meade 14 inch scope
• Meade 14" LX200-ACF (f/10)
Advanced Coma-Free w/UHTC #1410-60-03
•
•
•
•
•
USD$ 6,999.00
Schmidt-Cassegrain Focus
Aperture 14 inch (356 mm)
Focal Length 3556 mm
Focal Ratio f/10
2
3
Outline
A. Light Gathering Power and Magnitudes
B. Magnification
C. Resolution
D. References
4
A. LGP
1. Magnitude Scale
2. Limiting Magnitude
3. Star Counts
1. Magnitudes and Brightness
5
1.Magnitude Scale:
Hipparchus of Rhodes (160-127
B.C) assigns “magnitudes” to
stars to represent brightness.
The eye can see down to 6th
magnitude
1b Herschel Extends the Table
William Herschel (1738-1822) extended
the scale in both directions
6
1c Herschel-Pogson Relation
7
Herschel’s measurements suggested a 1st magnitude star is 100x more luminous
that a 6th magnitude one. Norman Pogson (1854) showed that this is because the
eye’s response to light is logarithmic rather than linear.
m  -2.5Logr 
22.5
C.3b
Gemini
Mag
MaMag
4 6
g
2
3
8
9
2a Light Gathering Power
• Aperture=diameter of objective mirror (14 inch)
• Light Gathering Power (aka Light Amplification)
is proportional to area of mirror
 Aperture objective
LGP  
Aperture eye

2
 356 mm 
  3520
 
 6 mm 



2
2b Limiting Magnitude
• Telescope LGP in magnitudes:
 m  2 .5 Log (3520 )   8 .87
• Limiting magnitude of naked eye is +6, hence
looking through scope we can see +14.8
• With streetlights, limiting magnitude is perhaps +3.5,
hence looking through scope we can see +12.3
10
3a Number of Stars by Magnitude
•There are only about 15 bright (first magnitude and brighter) stars
•There are only about 8000 stars visible to naked eye
•There are much more stars with higher magnitude!
11
3b Number of Stars by Magnitude
Stellar Counts
6
y = 0.4914x + 0.9204
R² = 0.9958
Log(Cumulative count)
5
4
3
2
1
0
-2
0
2
4
Limiting Magnitude
6
8
10
By extrapolating to magnitude 14.5, we might be able to see up to 100 million
stars in our galaxy!
Note, the galaxy has perhaps 100 billion stars.
12
B. Magnifying Power
1. Telescope Design
2. Magnification Power
3. Minimum Magnification
13
1a. Basic Telescope Design
Refractor Telescope (objective is a converging lens)
Focal Length of Objective is big
Focal Length of eyepiece is small
14
1b Newtonian Reflecting Telescope
• Objective is a concave (converging) mirror
• Focal length is approximately the length of tube
• Light is directed out the side for the eyepiece
15
1c Schmidt Cassegrain Telescope
• Cassegrain focus uses “folded optics” so the
focal length is more than twice the length of tube
• Light path goes through hole in primary mirror
• Schmidt design has corrector plate in front
16
2. Magnification Power
The overall magnification of the angular size is
given by the ratio of the focal lengths
Power  
Fobjective
Feyepiece
For our scope (F=3556 mm), with a 26 mm
eyepiece, the power would be:
3556 mm
Power  
 137 
26 mm
17
3a. Too Much Magnification?
• Extended objects (planets, nebulae, galaxies) when
magnified more will appear fainter
Low Power
High Power
18
3b. Too Much Magnification?
• Too much magnification and you won’t see it at all!
• Its about surface brightness! Your eye can’t see below a
certain amount.
Low Power
High Power
19
3c. Surface Brightness
• “S” Units: magnitudes per square arcseconds. For
object of total magnitude “m” over angular area “A” (in
square arcseconds):
S  m  2.5 Log ( A)
•
•
•
•
S=22 is an ideal sky
S=19 in suburbia
S=18 if full moon is up
S=17 in urban area
• Dumbbell Nebula has S=18.4, so if moon is up,
probably can’t see it, no matter how big of aperture
you have! Can never see it in an urban area!
20
3d. Exit Pupil, minimum magnification
• Lower power is better for faint diffuse objects, BUT If the
outgoing beam of light is bigger than aperture of eye (6
mm), the light is wasted!
• Maximum useful eyepiece
for our scope:
Fo
Fe  (6 mm)
 60 mm
Ao
• Minimum useful magnification: 60x
21
22
C. Resolution
1. Airy Diffraction
2. Limiting Resolution
3. Acuity of the Eye
1. Airy Diffraction
• Light through a circular aperture will diffract.
• Light from a point like object (distant star)
will appear as a “blob” with rings.
• Size of blob:
“A” is aperture,
 is wavelength
 in radians

  1.22
A
• For our telescope (A=356 mm), for 500nm
light the blob is 0.35”. (Limiting Optical
Resolution of scope).
23
2. Limiting Resolution
• If two stars are closer than the limiting resolution, the
“blobs” will overlap and you cannot “resolve” them.
• Observing close
double stars tests
the quality of your
optics.
• The maximum useful
magnification is when
the eye starts seeing these blobs, i.e. the diffraction disk is
magnified to 2’=120”. For our telescope, this is about at
120”/0.35”=342, so an eyepiece smaller than 10 mm will
start to show fuzzballs.
24
3 Acuity of the Eye
• Fovea of eye has best resolution (this is
what you are using to read)
• Smallest detail eye can resolve is perhaps
1’=60”
• Hence Saturn (20”) must be magnified at
least 3x for eye to resolve it into a disk.
• Example: with magnification power of 100x,
the smallest detail we can see is only
0.01’=0.6”
• Note, sky turbulence limits us to about 1”
25